An extracellular vesicle delivery platform based on the PTTG1IP protein

Extracellular vesicle Pub Date : 2024-10-23 DOI:10.1016/j.vesic.2024.100054

Carla Martin Perez , Xiuming Liang , Dhanu Gupta , Emily R. Haughton , Mariana Conceição , Imre Mäger , Samir EL Andaloussi , Matthew J.A. Wood , Thomas C. Roberts

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Abstract

Extracellular vesicles (EVs) are promising therapeutic delivery vehicles, although their potential is limited by a lack of efficient engineering strategies to enhance loading and functional cargo delivery. Using an in-house bioinformatics analysis, we identified N-glycosylation as a putative EV-sorting feature. PTTG1IP (a small, N-glycosylated, single-spanning transmembrane protein) was found to be a suitable scaffold for EV loading of therapeutic cargoes, with loading dependent on its N-glycosylation at two arginine residues. Chimeric proteins consisting of PTTG1IP fused with various cargo proteins, and separated by self-cleaving sequences (to promote cargo release), were shown to enable highly efficient functional delivery of Cre protein to recipient cell cultures and mouse xenograft tumors, and delivery of Cas9-sgRNA complexes to recipient reporter cells. The favorable membrane topology of PTTG1IP enabled facile engineering of further variants with improved properties, highlighting its versatility and potential as a platform for EV-based therapeutics.

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基于 PTTG1IP 蛋白的细胞外囊泡输送平台

细胞外囊泡（EVs）是一种很有前景的治疗递送载体，但由于缺乏有效的工程策略来提高载荷和功能性货物递送，其潜力受到了限制。通过内部生物信息学分析，我们发现 N-糖基化是一种潜在的 EV 分类特征。研究发现，PTTG1IP（一种小型、N-糖基化、单跨跨膜蛋白）是治疗货物装载的合适支架，其装载取决于两个精氨酸残基上的 N-糖基化。研究表明，由 PTTG1IP 与各种载体蛋白融合而成的嵌合蛋白，以自裂解序列分隔（促进载体释放），能将 Cre 蛋白高效地输送到受体细胞培养物和小鼠异种移植肿瘤中，并将 Cas9-sgRNA 复合物输送到受体报告细胞中。由于 PTTG1IP 具有良好的膜拓扑结构，因此可以方便地设计出性能更好的其他变体，从而凸显了它作为基于 EV 的治疗平台的多功能性和潜力。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Extracellular vesicle Biochemistry, Genetics and Molecular Biology (General)

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审稿时长

43 days